KT precast slabs,as an alternative method to traditional wooden formwork, have a major drawback: the cost associated with their self-weight. Ultra-High Performance Concrete (UHPC) possesses extremely high mechanical strength, including compressive and tensile strengths that are several times of traditional concrete. In this study ,UHPC is uesd as the material for KT-slab concrete board in order to improve the weakness of KT-slabs. Through the high strength of UHPC, KT-slabs can reduce their thickness while maintaining the same strength. The design of KT-slabs is divided into two parts: the service load during the grouting phase, and the ultimate strength of the composite KT floor after completion. This study drafts strength estimation formulas for various checkpoints in both phases and designs five sets of slab specimens for each phase to conduct four-point unidirectional flexural tests. These tests experimentally verify the applicability of the formulas on UHPC KT-slabs. The operational variables of the specimens include two types of fibers mixed into the UHPC and the thickness of the KT-slab concrete boards. According to material tests, this study confirms that UHPC materials may exhibit significant differences in mechanical behavior depending on the type of fibers or different powder mixtures. Based on the results, a tensile stress-strain design curve for KT-slab is formulated. According to the KT-slab experiment results, the estimations of cracking strength and buckling strength are quite accurate, but the experimental values of stiffness of the steel fiber UHPC specimen is lower than estimated values, indicating that the formulas are not conservative. According to the composite floor experiment results, the ultimate strength prediction formulas are quite accurate for the 27 mm thick KT-slab specimens, but overly conservative for the extremely thin 18 mm KT-slab specimens.